Filtered antenna assembly

ABSTRACT

An antenna assembly for a wireless communications device has an antenna, a filter circuit, and a connector constructed to engage a wireless communications device. A filter circuit includes a band-pass filter and a first notch filter disposed in serial electrical communication with the band-pass filter, the band-pass filter operable to permit the passage of oscillatory electrical signals in a first frequency range, the first notch filter operable to impede the passage of oscillatory electrical signals in a second frequency range, the second frequency range residing within the first frequency range.

CROSS REFERENCE TO RELATED APPLICATION

This application is a continuation of and claims priority fromco-pending U.S. patent application Ser. No. 11/857,558 filed on Sep. 19,2007 and entitled FILTEREND ANTENNA ASSEMBLY, incorporated herein byreference.

BACKGROUND

These descriptions relate generally to antenna assemblies for engagingthe antenna connectors of wireless communications devices, and relatemore particularly relate to antenna assemblies having filter circuitswithin compact constructions.

Wireless internet-service routers typically exchange data with one ormore computing devices by way of an antenna connected to the router. Arouter typically has one or more antenna connectors for engaging theantenna. A router may have on-board filter circuits, but on-board filtercircuits are typically adapted to convey out-going and incoming datatraffic, within the router, between the antenna and the transmit andreceive circuit portions of the router. The on-board filter circuits arenot successful in all environments with regard to suppressinginterference signals generated by other devices. For example, wirelessinternet-service routers are susceptible to performance degradation dueto the unwanted presence of interference signals coming from otherdevices such as microwave ovens and cordless telephones. Ironically, thevery environments to which wireless routers are adapted to provideconvenience, environments such as homes and offices, are typicallyinhabited by these other devices that generate unwanted interferencesignals.

Thus, a need exists for an improved antenna assembly that includes afilter circuit to facilitate the use of a wireless communications devicein an environment where interference sources reside. A clutter-free andeasily installed assembly that pre-filters interference signals fromdata traffic at the antenna stage of data routing is needed.

SUMMARY

The present invention addresses the above needs and enables otheradvantages, by providing antenna assemblies having filter circuits. Forexample, according to at least one aspect of the invention, an antennaassembly for a wireless communications device includes an antenna, afilter circuit in electrical communication with the antenna, and aconnector in electrical communication with the filter circuit. Theconnector is constructed to dispose a wireless communications deviceinto electrical communication with the filter circuit by engaging thewireless communications device. The antenna assembly is capable of atleast wirelessly receiving data by way of the antenna and providing thereceived data to the wireless communications device by way of theantenna and the connector when the connector engages the wirelesscommunications device. The filter circuit may include a band-pass filteroperable to permit the passage of oscillatory electrical signals betweenthe antenna and the connector in a first frequency range. The filter mayalso include a first notch filter operable to impede the passage ofoscillatory electrical signals in a second frequency range which iswithin the first frequency range.

In at least one embodiment, the second frequency range resides withinthe first frequency range such that the filter circuit is operable topermit the passage of oscillatory electrical signals in at least twofrequency sub-ranges within the first frequency range, the twosub-ranges separated by the second frequency range. In at least oneembodiment, the filter includes a second notch filter operable to impedethe passage of oscillatory electrical signals in a third frequency rangewhich is within the first frequency range. In at least one embodiment,the filter circuit defines a pre-filter for a wireless internet-servicerouter. In at least one example, the first frequency range includesfrequencies between 2400 mega-hertz and 2462 mega-hertz. In anotherexample, the first frequency range includes frequencies between 5150mega-hertz and 5825 mega-hertz.

The antenna, filter circuit and connector define a unitary constructionin at least one embodiment of the antenna assembly. In anotherembodiment, the antenna and filter circuit define a unitary constructionpivotally attached to the connector. In yet another embodiment, theconnector and filter circuit define a unitary construction pivotallyattached to the antenna.

BRIEF DESCRIPTION OF THE SEVERAL VIEWS OF THE DRAWINGS

Having thus described the invention in general terms, reference will nowbe made to the accompanying drawings, which are not necessarily drawn toscale, and wherein:

FIG. 1 is a diagrammatic representation of an antenna assembly having anantenna, a filter circuit, and a connector in accordance with a firstembodiment of the invention;

FIG. 2 is a representation of a transmission function of the filtercircuit of FIG. 1;

FIG. 3 is a diagrammatic representation of an antenna assembly having anantenna, a filter circuit, and a connector in accordance with a secondembodiment of the invention;

FIG. 4 is a representation of a transmission function of the filtercircuit of FIG. 3;

FIG. 5 is a diagrammatic representation of an exemplary embodiment of aband-pass filter, which the filter circuits of FIGS. 1 and 3 mayinclude;

FIG. 6 is a diagrammatic representation of an exemplary embodiment of anotch filter, which the filter circuits of FIGS. 1 and 3 may include;

FIG. 7 is a perspective view of an antenna assembly, according to eitherof the embodiments of FIGS. 1 and 3, in which the antenna and filtercircuit define a unitary construction pivotally attached to theconnector; and

FIG. 8 is a perspective view of an antenna assembly, according to eitherof the embodiments of FIGS. 1 and 3, in which the connector and filtercircuit define a unitary construction pivotally attached to the antenna.

DETAILED DESCRIPTION

The present invention now will be described more fully hereinafter withreference to the accompanying drawings in which some but not allembodiments of the inventions are shown. Indeed, these inventions may beembodied in many different forms and should not be construed as limitedto the embodiments set forth herein; rather, these embodiments areprovided so that this disclosure will satisfy applicable legalrequirements. Like numbers refer to like elements throughout.

An antenna assembly 100 in accordance with a first embodiment of theinvention is diagrammatically represented in FIG. 1. The antennaassembly 100 includes an antenna 102, a filter circuit 104, and aconnector 106. The filter circuit defines a pre-filter for a wirelesscommunications device 10 involved in wireless communications, which maybe two-way communications, through the antenna assembly 100. Thewireless communications device 10 may include its own on-board filtercircuits. Thus, the filter circuit 104 may supplement, improve, orobviate on-board filtering capabilities of the wireless communicationdevice 10. The connector 106 is constructed to engage the connector 12of the device 10. The connectors 12 and 106 comprise respectiveelectrically conductive contact members through which the device 10 andthe antenna assembly 100 are in electrical communication when theconnectors are engaged. For example, in at least one embodiment, theconnector 106 is a conventional coaxial connector in male configurationthat engages the connector 12 which is a conventional coaxial connectorin female configuration. In that example, the contact members of theconnectors are the centrally disposed conducting members of theconventional coaxial connectors. The connectors may include additionalconducting members that engage each other. For example, the connectorsmay include shield or grounding members such as the outer sleeveportions of conventional coaxial connectors.

The connector 106 is in electrical communication with the antenna 102through the filter circuit 104. The antenna assembly 100 is generallyadapted to facilitate wireless communications of the wirelesscommunications device 10. Accordingly, the filter circuit 104 permitsthe passage of oscillatory electrical signals, in one or more particularfrequency ranges, between the antenna 102 and the contact member of theconnector 106. For example, in the illustrated embodiment the filtercircuit 104 includes a band-pass filter 108 operable to permit thepassage of oscillatory electrical signals in a first frequency range 208(FIG. 2). The first frequency range may vary among various embodimentsof the band-pass filter 108 in order for the communications of variouswireless communications devices 10, having various communicationfrequency ranges, to be facilitated. Signals within any givencommunication frequency range may be called in-band signals. Signals atfrequencies above and below any given communication frequency range maybe called out-of-band signals. The band-pass filter 108 permits thepassage of signals in the communication frequency range of the wirelesscommunications device 10 and impedes the passage of oscillatoryelectrical signals outside of that frequency range in order to preventout-of-band interfering signals from reaching the wirelesscommunications device and to prevent out-of-band signals from beingtransmitted by the wireless communications device through the antenna.The electrical oscillatory signals received by the antenna may have manyfrequency components. Impeding signals at any particular frequencyrelates to entirely blocking signals at that frequency or attenuatingsignals at that frequency to reduce or suppress their intensities asthey propagate across the filter circuit in some diminished amount.

In at least one example, the wireless communications device 10 is awireless internet-service router operating in the 2400 to 2462 megahertzfrequency range and having a conventional coaxial connector 12 forengaging an antenna. In that example, the connector 106 engages theconnector 12 and the band-pass filter permits the passage of in-bandoscillatory electrical signals in this range between the connector 106and the antenna 102 while impeding out-of-band signals havingfrequencies below 2400 megahertz and above 2462 megahertz. Furthermore,in that example, the wireless communications conducted by the device 10include two-way communications. That is, data can be downloaded from theinternet and transmitted from the antenna 102 to a user's computingdevice, and data to be uploaded to the internet can be received by theantenna 102 from the computing device. In another example, the wirelesscommunications device 10 is a wireless internet-service router operatingin the 5150 to 5825 megahertz frequency range and the band-pass filteraccordingly permits passage of oscillatory electrical signals in thisrange between the connector 106 and the antenna 102 while impedingsignals having frequencies below 5150 megahertz and above 5825megahertz. In these examples, the data link 14 in FIG. 1 represents therouter's connection to the internet.

The filter circuit 104 may also impede the passage of signals in one ormore frequencies or frequency ranges in which interferences are found orknown to reside. For example, microwave ovens and cordless telephonesmay represent in-band interferences in some wireless communicationfrequency ranges. Accordingly, the filter circuit 104 may impede thepassage of signals in the frequencies of such interferences whilepermitting the passage of signals above and below the interferences. Forexample, in the illustrated embodiment the filter circuit 104 includes anotch filter 110 operable to impede the passage of oscillatoryelectrical signals in a second frequency range 210 (FIG. 2). The notchfilter 110 is disposed in serial electrical communication with theband-pass filter 108 and works in conjunction with the band-pass filterto facilitate wireless communications of the wireless communicationsdevice 10. Accordingly, the second frequency range is chosen within thefirst frequency range, which includes a wireless communication frequencyrange of the wireless communications device 10. The second frequencyrange may vary among various embodiments of the notch filter 110 inorder that each embodiment impedes interferences from one or moreparticular interference sources. Thus, in each particular embodiment ofthe notch filter, the second frequency is chosen to coincide orencompass the frequencies of interference signals found or known toreside within the wireless communication frequency range of the wirelesscommunications device 10.

By combining the operational effects of the band-pass filter 108 and thenotch filter 110, the filter circuit 104 exhibits a transmissionfunction as represented in FIG. 2. The frequency axis 202 represents anyfrequency domain that includes a communication frequency range of thewireless communications device 10. As varying examples of such wirelesscommunications devices have varying communication frequency ranges, thefrequency axis 202 is provided as generic and without particular units.The transmission axis 204 represents the relative intensity of a signalpassing through the filter circuit 104 and is also provided withoutparticular units. In the illustrated transmission function 200, thefirst frequency range 208 permitted by the band-pass filter 108 (FIG. 1)is chosen to correspond to the communication frequency range of aparticular wireless communications device 10. Thus, in one examplewherein the wireless communications device 10 is a wirelessinternet-service router operating in the 2400 to 2462 megahertzfrequency range, the first frequency range 208 in FIG. 2 is anapproximate 2400 to 2462 megahertz frequency range. In another examplewherein the wireless communications device 10 is a wirelessinternet-service router operating in the 5150 to 5825 megahertzfrequency range, the first frequency range 208 in FIG. 2 is anapproximate 5150 to 5825 megahertz frequency range. The second frequencyrange 210 illustrated within the first frequency range 208 in FIG. 2represents a particular frequency impeded by the notch filter 110 (FIG.1).

The second frequency range 210 (FIG. 2) resides within the firstfrequency range 208. Thus, the transmission function 200 exhibits twofrequency sub-ranges 212 and 214 in which oscillatory electrical signalsare passed by the filter circuit 104 (FIG. 1.). The two frequencysub-ranges 212 and 214 are separated by the second frequency range 210.Thus, the notch filter 110 is configured to impede known or foundinterferences within the communication frequency range of the wirelesscommunications device 10 (FIG. 1). The band-pass filter permits thepassage of signals in the first frequency range 208, and the notchfilter impedes signals in the second frequency range 210. Thiscorresponds to permitting signals in the communication frequency rangeof a wireless communications device and impeding interfering signalswithin that communication frequency range.

An antenna assembly 300 in accordance with another embodiment of theinvention is diagrammatically represented in FIG. 3. Like the antennaassembly 100 of FIG. 1, the antenna assembly 300 of FIG. 3 includes anantenna 302, a filter circuit 304, and a connector 306 constructed toengage a wireless communications device. The assemblies 100 and 300 bearmany similarities and therefore the preceding descriptions need not beduplicated. The antenna assembly 300 differs from the precedingdescriptions in that the filter circuit 304 includes a band-pass filter308 in serial electrical communication with two notch filters 310 and312. The band-pass filter 308 permits the passage of oscillatoryelectrical signals in a first frequency range 408 (FIG. 4), and the twonotch filters 310 and 312 impede signals in two respective frequencyranges 410 and 412 (FIG. 4). Thus, the antenna assembly 300 facilitateswireless communications in an environment where interference signals areknown or found to reside in the two frequency ranges 410 and 412.

By combining the operational effects of the band-pass filter 308 and thenotch filters 310 and 312, the filter circuit 304 exhibits thetransmission function 400 represented in FIG. 4. The first frequencyrange 408 permitted by the band-pass filter 308 extends along thefrequency axis 402. Frequency sub-ranges permitted by the filter circuitare represented as rises in the transmission function along thetransmission axis 404. Within the first frequency range 408, thetransmission function exhibits dips at the frequency ranges 410 and 412impeded respectively by the notch filters 310 and 312. Thus, the notchfilters 310 and 312 are configured to impede known or foundinterferences within the first frequency range 408. This corresponds topermitting signals in the communication frequency range of a wirelesscommunications device and impeding interfering signals within thatcommunication frequency range.

In view of the filter circuit 104 having a single notch filter 110 inFIG. 1, and in view of the filter circuit 304 having two notch filters310 and 312 in FIG. 3, it is clear that various embodiments of theinvention may include various numbers of notch filters chosen to impedeparticular interferences in various frequency ranges within thecommunication frequency range of a wireless communications device. Thus,wireless communications are facilitated in various environments havinginterfering signals within multiple frequency ranges.

Within the scope of these descriptions, the band-pass filters 108 and308 may be of various types. For example, the band-pass filters may eachbe a full transform elliptic band-pass filter 500 as represented in FIG.5. In FIG. 5, multiple tank elements “T” are in serial communicationwith each other to define a transmission path 502. Each tank elementincludes a capacitor “C” and an inductor “L” arranged in parallelcommunication with each other. Multiple shunt elements S are connectedbetween the transmission path and ground. Each shunt element includes acapacitor and an inductor. To avoid needless repetition, only oneinductor “L,” one capacitor “C,” one tank element “T,” and one shuntelement “S” are labeled in FIG. 5. The band-pass filter 500 can beunderstood to: permit the passage of oscillatory electrical signals in aparticular frequency range along the transmission path according toresonances in the tank elements; and, impede signals above and belowthat particular frequency range as low and high frequency signals areshunted to ground respectively by the inductors and capacitors of theshunt elements. The capacitance values of the capacitors and theinductance values of the inductors may be chosen in the making of anyparticular band-pass filter to permit passage of signals along thetransmission path in a desired particular frequency range, which relatesto the first frequency ranges 208 and 408 in FIGS. 2 and 4. The fulltransform elliptic band-pass filter 500 in FIG. 5 merely represents anexample. The band-pass filters 108 and 308 may each be among other typesof band-pass filters.

Furthermore, within the scope of these descriptions, the notch filters110, 310 and 312 may be of various types. For example, the notch filtersmay each be a full transform elliptic notch filter 600 as represented inFIG. 6. In FIG. 6, multiple tank elements “T” are in serialcommunication with each other to define a transmission path 602. Eachtank element includes a capacitor “C” and an inductor “L” arranged inparallel communication with each other. Multiple shunt elements S areconnected between the transmission path and ground. Each shunt elementincludes a capacitor and an inductor in serial electrical communicationwith each other. To avoid needless repetition, only one inductor “L,”one capacitor “C,” one tank element “T,” and one shunt element “S” arelabeled in FIG. 6. The notch filter 600 can be understood to: permit thepassage of low-frequency oscillatory electrical signals along thetransmission path by way of the inductors of the tank elements; permitthe passage of high-frequency oscillatory electrical signals along thetransmission path by way of the capacitors of the tank elements; and,impede signals in a particular frequency range according to resonancesin the shunt elements which shunt signals in that range from thetransmission path to ground. The capacitance values of the capacitorsand the inductance values of the inductors may be chosen in the makingof any particular notch filter to impede signals in a desired particularfrequency range, which relates to the frequency ranges 210, 410, and 412in FIGS. 2 and 4. The full transform elliptic notch filter 600 in FIG. 6merely represents an example. The notch filters 110, 310 and 312 mayeach be among other types of notch filters.

Regarding either of FIGS. 1 and 3, any particular filter circuit (104,304) constructed in accordance with an embodiment of the invention maybe constructed as a miniaturized filter circuit for minimizing the sizeof any of the described unitary constructions. This is advantageoustoward providing an antenna assembly having an integral filter in acompact unit, which may include a pivoting joint. The filter circuit maybe manufactured according to Micro-Electro-Mechanical Systems (MEMS)fabrication techniques and accordingly may be provided at a size that isadvantageously small in comparison to typical earlier filter circuits.

Again regarding either of FIGS. 1 and 3, the antenna assembly (100, 300)advantageously filters out unwanted interference signals before suchsignals enter the device with which the antenna assembly is engaged. Theband-pass filter (108, 308) impedes out-of-band signals with regard tothe communication frequency range of the engaged device, and one or morenotch filters (110, 310, 312) impede in-band interferences.Advantageously, the engagement of the antenna assembly with a device isconveniently accomplished using a single connector (106, 306).

Furthermore, regarding either of FIGS. 1 and 3, according to at leastone embodiment of the invention, the antenna (102, 302), the filtercircuit (104, 304), and the connector (106, 306) define a unitaryconstruction for convenience of handling and use. In an exemplaryscenario, a user grasps the unitary construction and engages theconnector thereof with a wireless communications device 10 (FIG. 1). Theengagement disposes the contact member of the connector (106,306) intoelectrical communication with a corresponding contact member of theconnector 12 of the wireless communications device. The wirelesscommunications device then at least receives wireless communicationsthrough the antenna assembly (100, 300) while benefiting from theoperational effects of the filter circuit (104, 304), and whilebenefiting from the convenience, elegance, and simplicity of a unitaryconstruction. This embodiment may be particularly advantageous for usewith hand-held radios. It should be understood that these descriptionsrelate to a wireless communications device that both receives andtransmits wireless communications through the antenna assembly (100,300).

Furthermore yet, regarding either of FIGS. 1 and 3, according to atleast one other embodiment of the invention, the antenna (102, 302) andthe filter circuit (104, 304) define a unitary construction pivotallyattached to the connector (106, 306). An exemplary embodiment of such anantenna assembly is shown in FIG. 7. The antenna assembly 700 includes aunitary construction 720 pivotally attached to the connector 706. Theunitary construction is defined by the antenna 702 and the filtercircuit 704, which are disposed within a common housing 722. In thisexemplary embodiment: the antenna 702 relates to the antennas 102(FIGS. 1) and 302 (FIG. 2); the filter circuit 704 relates to the filtercircuits 104 (FIGS. 1) and 304 (FIG. 3); and the connector 706 relatesto the connectors 106 (FIGS. 1) and 306 (FIG. 2). Within the housing722, the filter circuit 704 contacts the housing for grounding purposes,such as for shunting signals filtered from the transmission path definedacross the filter circuit between the pins 724 and 726 by which thefilter circuit maintains electrical contact with the antenna 702 andconnector 706, respectively. The pins 724 and 726 respectively representsignal input and output pins of the filter circuit when the antennaassembly 700 receives wireless signals through the antenna. Conversely,the pins 724 and 726 respectively represent signal output and input pinsof the filter circuit when the antenna assembly transmits wirelesssignals from the antenna. The unitary construction 720 pivots about ahinge pin 728 relative to the connector 706 to permit adjustment of thedisposition of the antenna 702. This exemplary embodiment may beparticularly advantageous for use in an environment where varying thedisposition of the antenna may promote signal strength or reduceinterferences.

Moreover, in at least one other embodiment of the invention, theconnector (106, 306) and the filter circuit (104, 304) define a unitaryconstruction pivotally attached to the antenna (102, 302). An exemplaryembodiment of such an antenna assembly is shown in FIG. 8. The antennaassembly 800 includes a unitary construction 820 pivotally attached tothe antenna 802. The unitary construction is defined by the connector806 and the filter circuit 804, which are disposed within a commonhousing 822. In this exemplary embodiment: the antenna 802 relates tothe antennas 102 (FIGS. 1) and 302 (FIG. 2); the filter circuit 804relates to the filter circuits 104 (FIGS. 1) and 304 (FIG. 3); and theconnector 806 relates to the connectors 106 (FIGS. 1) and 306 (FIG. 2).Within the housing 822, the filter circuit 804 contacts the housing forgrounding purposes, such as for shunting signals filtered from thetransmission path defined across the filter circuit between the pins 824and 826 by which the filter circuit maintains electrical contact withthe antenna 802 and connector 806, respectively. The pins 824 and 826respectively represent signal input and output pins of the filtercircuit when the antenna assembly 800 receives wireless signals throughthe antenna. Conversely, the pins 824 and 826 respectively representsignal output and input pins of the filter circuit when the antennaassembly transmits wireless signals from the antenna. The unitaryconstruction 820 pivots about a hinge pin 828 relative to the antenna802 to permit adjustment of the disposition of the antenna 802. Likethat of FIG. 7, the exemplary embodiment of FIG. 8 may be particularlyadvantageous for use in an environment where varying the disposition ofthe antenna may promote signal strength or reduce interferences.

Many modifications and other embodiments of the inventions set forthherein will come to mind to one skilled in the art to which theseinventions pertain having the benefit of the teachings presented in theforegoing descriptions and the associated drawings. Therefore, it is tobe understood that the inventions are not to be limited to the specificembodiments disclosed and that modifications and other embodiments areintended to be included within the scope of the appended claims.Although specific terms are employed herein, they are used in a genericand descriptive sense only and not for purposes of limitation.

1. An antenna assembly for a wireless communications device, the antennaassembly comprising: an antenna for wirelessly receiving data; a filtercircuit in electrical communication with the antenna; a connector inelectrical communication with the filter circuit, the connectorconstructed to dispose a wireless communications device into electricalcommunication with the filter circuit by engaging the wirelesscommunications device; wherein the antenna, filter circuit, andconnector collectively form a unit that terminates at the connector,whereby when the connector is in engagement with the wirelesscommunications device the received data is provided to the wirelesscommunications device by way of the filter circuit and the connector. 2.The antenna assembly according to claim 1, the filter circuit comprisinga band-pass filter operable to permit the passage of oscillatoryelectrical signals between the antenna and the connector in a particularfrequency range.
 3. The antenna assembly according to claim 1, thefilter circuit comprising a notch filter operable to impede the passageof oscillatory electrical signals between the antenna and the connectorin a particular frequency range.
 4. The antenna assembly according toclaim 1, the filter circuit comprising a band-pass filter and a firstnotch filter disposed in serial electrical communication with theband-pass filter, the band-pass filter operable to permit the passage ofoscillatory electrical signals between the antenna and the connector ina first frequency range, the first notch filter operable to impede thepassage of oscillatory electrical signals between the antenna and theconnector in a second frequency range, the second frequency rangeresiding within the first frequency range.
 5. The antenna assemblyaccording to claim 4, the second frequency range residing within thefirst frequency range such that the filter circuit is operable to permitthe passage of oscillatory electrical signals in at least two frequencysub-ranges within the first frequency range, the two sub-rangesseparated by the second frequency range.
 6. The antenna assemblyaccording to claim 4, comprising a second notch filter, the second notchfilter disposed in serial electrical communication with at least one ofthe band-pass filter and the first notch filter, the second notch filteroperable to impede the passage of oscillatory electrical signals betweenthe antenna and the connector in a third frequency range, the thirdfrequency range residing within the first frequency range.
 7. Theantenna assembly according to claim 4, the first frequency rangeincluding frequencies between 2400 mega-hertz and 2462 mega-hertz. 8.The antenna assembly according to claim 4, the first frequency rangeincluding frequencies between 5150 mega-hertz and 5825 mega-hertz. 9.The antenna assembly according to claim 1, the connector constructed tomount onto an antenna-connector of a wireless internet-service router.10. The antenna assembly according to claim 1, the filter circuitdefining a pre-filter for a wireless internet-service router.
 11. Theantenna assembly according to claim 1, the antenna and filter circuitdefining a unitary construction pivotally attached to the connector. 12.The antenna assembly according to claim 1, the connector and filtercircuit defining a unitary construction pivotally attached to theantenna.
 13. An antenna assembly for a wireless communications device,the antenna assembly comprising: an antenna for wirelessly receivingdata; a filter circuit in electrical communication with the antenna; aconnector in electrical communication with the filter circuit, theconnector constructed to dispose a wireless communications device intoelectrical communication with the filter circuit by engaging thewireless communications device; wherein the antenna and the filtercircuit form a unitary construction pivotally connected to theconnector, and wherein when the connector is in engagement with thewireless communications device the received data is provided to thewireless communications device by way of the filter circuit and theconnector.
 14. The antenna assembly according to claim 13, the filtercircuit comprising a band-pass filter and a first notch filter disposedin serial electrical communication with the band-pass filter, theband-pass filter operable to permit the passage of oscillatoryelectrical signals between the antenna and the connector in a firstfrequency range, the first notch filter operable to impede the passageof oscillatory electrical signals between the antenna and the connectorin a second frequency range, the second frequency range residing withinthe first frequency range.
 15. The antenna assembly according to claim14, the second frequency range residing within the first frequency rangesuch that the filter circuit is operable to permit the passage ofoscillatory electrical signals in at least two frequency sub-rangeswithin the first frequency range, the two sub-ranges separated by thesecond frequency range.
 16. The antenna assembly according to claim 14,comprising a second notch filter, the second notch filter disposed inserial electrical communication with at least one of the band-passfilter and the first notch filter, the second notch filter operable toimpede the passage of oscillatory electrical signals between the antennaand the connector in a third frequency range, the third frequency rangeresiding within the first frequency range.
 17. An antenna assembly for awireless communications device, the antenna assembly comprising: a meansfor wirelessly receiving a signal; a means for filtering the signal inelectrical communication with the antenna; a connecting means inelectrical communication with the means for filtering the signal, theconnecting means constructed to dispose a wireless communications deviceinto electrical communication with the means for filtering the signal byengaging the wireless communications device; wherein the means forwirelessly receiving the signal, the means for filtering the signal, andthe connecting means form a unit that terminates at the connectingmeans, whereby when the connecting means is in engagement with thewireless communications device the received data is provided to thewireless communications device by way of the means for filtering thesignal and the connecting means.
 18. The antenna assembly according toclaim 17, the means for filtering the signal comprising a band-passfilter and a first notch filter disposed in serial electricalcommunication with the band-pass filter, the band-pass filter operableto permit the passage of oscillatory electrical signals between theantenna and the connector in a first frequency range, the first notchfilter operable to impede the passage of oscillatory electrical signalsbetween the antenna and the connector in a second frequency range, thesecond frequency range residing within the first frequency range. 19.The antenna assembly according to claim 18, the second frequency rangeresiding within the first frequency range such that the means forfiltering the signal is operable to permit the passage of oscillatoryelectrical signals in at least two frequency sub-ranges within the firstfrequency range, the two sub-ranges separated by the second frequencyrange.
 20. An antenna assembly according to claim 18, comprising asecond notch filter, the second notch filter disposed in serialelectrical communication with at least one of the band-pass filter andthe first notch filter, the second notch filter operable to impede thepassage of oscillatory electrical signals between the means forwirelessly receiving the signal and the connecting means in a thirdfrequency range, the third frequency range residing within the firstfrequency range.